KR20080091133A - A method for transition between distributed transmission and localized transmission - Google Patents

Abstract

A transition method between the distributed transmission and localized transmission is provided to reduce the upstream link signalling overhead without reducing the transmission gain. A measurement control message is transmitted to a user terminal from a BS(base station). The user terminal performs the measurement, and transmits the requested measurement report message to the BS. The BS transmits the transition indicator message to the user terminal on the basis of the measurement report message transmitted from the user terminal. A process for reporting the CQI(channel quality indicator) of the new mode between the user terminal and the BS, and performing the down link transmission is performed. The mode is formed of the distributed transmission mode and the local transmission mode. The distributed transmission mode reports the single CQI of the whole frequency band to the BS corresponding to the user terminal. The local transmission mode reports the CQIs of the sub-frequency band to the BS corresponding to the user terminal.

Description

A METHOD FOR TRANSITION BETWEEN DISTRIBUTED TRANSMISSION AND LOCALIZED TRANSMISSION}

The present invention relates to a wireless communication system supporting a centralized data transmission mode and a distributed data transmission mode, and more particularly, to a transition between the two modes.

Currently, the third generation mobile communication system partnership project (called "3GPP") standardization organization is in the process of Long-Term Evolution (called "LTE") for existing system standards. Among many physical layer transmission schemes, Orthogonal Frequency Division Multiplex (OFDM) is expected to be one of the downlink solutions because OFDM has advantages such as high spectrum utilization efficiency and low processing complexity. .

Basically, OFDM is a multi-carrier modulation communication technique. The OFDM basic principle is to divide a high speed data stream into a plurality of low speed data streams so that orthogonal subcarriers transmit simultaneously through a group. Due to the characteristics of the multi-carrier, the OFDM scheme has excellent performance in several ways. (1) The notable superiority of the OFDM technique is that inter-symbol interference is achieved when the channel delay is less than the length of the cyclic prefix (CP) (introduced by adding a guard interval to each symbol); ISI) can be completely eliminated because data is transmitted in parallel over multiple subcarriers, correspondingly increasing the symbol length on each subcarrier but not having sensitivity to channel delay. . For this reason, each subcarrier suffers from a flat fading channel state. (2) OFDM technique has high spectrum utilization efficiency. In the frequency domain, OFDM signals actually overlap. This overlap greatly improves the efficiency of spectrum utilization. (3) The OFDM technique has a strong ability in resisting anti-narrowband interference or frequency selective fading. In OFDM, through channel coding and interleaving, a frequency diversity effect and a time diversity effect can be obtained to effectively resist narrowband interference or frequency selective fading. (4) In the OFDM scheme, modulation is implemented through a baseband IFFT (Inverse Fast Fourier Transform), where IFFT / FFT provides an available high speed computation method and can be conveniently implemented in DSP chips and hardware structures.

In an OFDM wireless communication system, there are two transmission modes, namely, a concentrated transmission mode and a distributed transmission mode.

Centralized data transmission refers to sequentially transmitting data through subcarriers of a centralized subband, and a network end may specify an effective modulation and coding method for the data transmission based on channel quality between the BS and the UE. Implement adaptive modulation coding, thus increasing data transmission throughput. In addition, the distributed transmission mode means that the UE transmits data over the entire frequency band using comb-shaped subcarriers, so that the subcarriers for transmitting data are distributed to all frequency bands to the maximum, and accordingly Maximize the frequency diversity gain. Typically, the centralized data transmission mode, which can use adaptive modulation coding and frequency scheduling, has a larger transmission gain. However, in some rapidly changing channels, the channel state predicted at a particular point in time cannot reflect the channel state of the next point in time, which makes it difficult to implement concentrated transmission. Thus, distributed data transmission modes are often used for data transmission for frequency diversity gain.

During the downlink data transfer process:

In the case of the concentrated transmission mode, the UE measures the channel quality for each subband of the system frequency band, and then reports the measured channel quality indicator (CQI) of each subband to the base station BS. . Having received the CQIs, the BS determines whether to allocate frequency resources to the UE for data transmission in consideration of the CQI reported from each UE and the current system load, and what intensive frequency band to allocate to the UE. In order to achieve the goals of frequency scheduling and adaptive modulation coding (AMC) for data transmission, the UE continuously measures and measures channel quality for each subband of the system frequency band during the data transmission process. It is necessary to send the CQI to the base station. In this way, the maximum throughput of data transmission can be reached.

In the distributed transmission mode, the UE measures the average panel quality of the entire system frequency band and then reports a single average CQI to the base station BS. Having received the average CQI, the BS determines whether to allocate distributed frequency resources to the UE according to the CQI reported from each UE and the current system load. In order to achieve the goals of frequency scheduling and adaptive modulation coding (AMC) for data transmission, the UE also needs to continuously measure the average CQI of the entire system frequency band during the data transmission process and transmit the measured CQI to the base station. . In this way, the maximum throughput of data transmission can be reached.

As can be seen from the above description, the content of the measurement report transmitted from the UE to the BS in the centralized transmission mode is the CQI in the subband, and in the distributed transmission mode, the UE transmits only a single average CQI to the BS. Thus, the number of bits required to transmit CQI information in the centralized transmission mode is much larger than the number of bits in the distributed transmission mode.

In an LTE system, the system selects an appropriate transmission mode for data transmission between the BS and the UE based on the channel condition between the BS and the UE. When the channel state between the BS and the UE changes, there is a high possibility that a transition between the centralized transmission and the distributed transmission occurs.

The existing IEEE802.16E wireless transmission scheme defines the transition between the two transmission modes. 1 shows a flow diagram of a transition process signaling from distributed transmission to centralized transmission. The steps performed are as follows.

The UE checks the maximum value of the standard deviation in the time domain of the SNR measured in all subcarriers, so that when the maximum value is kept below a predetermined threshold and the average SNR of the entire frequency band is larger than the predetermined threshold, the UE is distributed. The transition indicator from the transmission mode to the concentrated transmission mode is transmitted to the BS (101). After the BS receives the transition indicator, it will send a channel measurement report request (REP-REQ) to the UE (102). After the UE receives the measurement report request, it sends a channel measurement report response (REP-RSP) to the BS (103), wherein the REP-RSP message includes channel quality indicators of the five frequency subbands with the best channel quality. do. At the start of the next frame after sending the REP-RSP message, the UE will send 104 a difference CQI report in the time domain of the selected frequency band to the BS. The BS transmits the centralized channel assignment to the UE based on the CQI reported by the UE (105) and performs the centralized data transmission to the UE (106).

2 shows a flow diagram of a signaling process transition from a centralized transmission mode to a distributed transmission mode, the steps carried out are as follows.

The UE checks the maximum value of the standard deviation in the time domain of the SNR measured on all subcarriers, and if this maximum value is larger than a predetermined threshold for a period of time, the UE sends an indication of the transition indicator from the centralized transmission mode to the distributed transmission mode to the BS. Transmit (201), the UE transmits (202) the average CQI report of the entire frequency band to the BS. The UE then repeatedly transmits the transition indicator 201 from the centralized transmission mode to the distributed transmission mode and the average CQI report 202 of the entire frequency band until the BS transmits the distributed channel assignment 203 to the UE. The BS then sends 204 a distributed data transmission to the UE.

If the maximum of the standard deviation of the SNR measured in all frequency subbands in the time domain is relatively large, distributed transmission is suitable for the UE, and the maximum of the standard deviation of the SNR measured in all frequency subbands in the time domain is relatively small and the overall frequency If the average SNR of the band is larger than the predetermined threshold, it can be seen from the data transfer mode transition process method of IEEE802.16E that the concentrated transmission mode is suitable for the transmission mode of the UE. According to IEEE802.16E, since the time domain channel deviation of the UE moved at high speed has a relatively large deviation, and the time domain channel deviation of the UE moved at low speed has a relatively small deviation, the UE having distributed data transmission moved at high speed. For centralized and low-speed UEs, centralized data transmission is appropriate when the average SNR of the entire frequency band is high.

In the centralized transmission mode, since more uplink signaling is required to transmit CQI of several subbands, the corresponding uplink signaling load is weighted. However, in data transmission in a flat fading channel state, since the SNRs of all subcarriers are basically the same regardless of whether they are centralized data transmission carriers or distributed data transmission carriers, the centralized data transmission is more selective than the distributed data transmission. Since gains cannot be obtained, their adaptive modulated coding gains are basically the same regardless of whether they use distributed transmission or concentrated transmission. However, concentrated transmission requires uplink multi-band CQI reporting, which results in more weighted signaling than distributed transmission. In a flat fading channel, even if the UE is a slow-moving UE and the average SNR is relatively high, distributed data transmission can achieve the same selective frequency gain as in intensive data transmission, and the uplink signaling load is small, so distributed The data transfer mode is more suitable.

In addition, the standardized method of 3GPP defines that the network controls the transmission method of the UE, and the UE does not determine the transition of the data transmission mode. Therefore, mode transition in IEEE802.16E is not suitable for data transmission mode transition in 3GPP LTE.

Therefore, some improvement can be made to the mode transition method in IEEE802.16E, allowing the UE to use a more suitable transmission mode for transmitting data.

In order to optimize the mode transition process described above, it is necessary to define several new measurement reporting and measurement reporting processes. These measurement controls and reports can be transmitted via RRC signaling and physical layer signaling. There is an interface, such as a physical layer interface, and an RRC protocol defined in 3GPP for controlling radio resources between the UE and the BS. The BS configures the network resources used by the UE via an interface protocol and configures the UE's functions regarding control such as measurement, handover, and the like. The physical instrumentation interface between the UE and BS is primarily responsible for the exchange of physical signals, such as CQI reporting of existing systems. CQI reporting is performed through a channel structure defined by a given physical channel, such as a channel structure defined in 3GPP TS 25.211, or through a channel structure defined in itself.

Based on the above-described problems, the present invention provides a data transmission mode transition method, wherein the BS can instruct the UE to transmit the necessary measurement report based on the channel state of the data transmission, and based on the measurement report The transmission mode of the UE may be indicated to the UE.

In order to achieve the above object, a method of transitioning between a distributed transmission mode and a concentrated transmission mode comprises the steps of: a) a BS sending a measurement control message to a UE; b) the UE performing the measurement and sending the requested measurement report message to the BS; c) the BS sending a new mode transition indicator message to the UE based on a measurement report message sent from the UE; And d) initiating a new mode CQI report and downlink transmission between the UE and the BS.

The present invention provides a transition method between centralized data transmission and distributed data transmission in downlink transmission, and FIG. 3 shows a signaling flowchart of the transition process. The process includes the following steps.

The BS may determine whether the transmission mode of the UE is converted according to service type information of the UE and information of the BS such as measurement. The BS determines whether some specified information reported by the UE should be used to determine the transmission mode transition, and if it determines that the measurement to be made by the UE can be configured, the measurement control message 301 of radio resource control signaling. The measurement control message includes a measurement to be performed by the UE (a measure of selectivity in the frequency domain for reflecting downlink channel fading) and a measurement report state. When the BS indicates the measurement report status, the measurement report threshold may be instructed to the UE, and may also indicate the period in which the UE reports the measurement report. After the UE receives the message, it measures according to the indicator and the specific measurement depends on the type of measurement. If the measurement of the UE satisfies the reporting status of the BS, the UE will send a measurement report message 302 to the BS, which may include a measurement report or other information of a particular measured value or event type. If the measurement report is an event type, it is appropriate to report the event to the BS if the UE's measurement is higher or lower than some threshold. Based on the measured value or the measurement event reported from the UE, the BS can determine in detail the behavior of the UE and send a new mode transition indicator 303 to the UE, instructing the UE to make a mode transition or a state transition. do. After the UE receives the transition indicator, a new mode of CQI reporting and downlink transmission 304 begins between the UE and the BS.

In the above process, 301, 302, and 303 are control signaling of all frequency resources, and the CQI report of 304 is physical layer signaling.

The downlink centralized transmission mode referred to in the present invention is a centralized CQI report, that is, reporting CQI of a plurality of frequency subbands, and means only a CQI reporting method of the UE in the mode, and is suitable for data transmission in a centralized resource. However, although the UE sends the centralized CQI report in this mode of transmission process, it does not preclude the BS from allocating data transmission to some distributed resources in several subframes. In this way, the downlink distributed transmission mode means that the CQI report transmitted by the UE is single in the frequency band, and is suitable to be transmitted in the distributed resource. However, although the UE transmits distributed CQI reports, the BS may allocate data transmissions to several concentrated resources in several subframes and is not excluded from the transmission process in this mode.

There are two processes for downlink transmission transition between centralized data transmission and distributed data transmission. One is the process of transitioning from the distributed transmission to the centralized transmission, and the other is the process of transitioning from the centralized transmission to the distributed transmission.

Here, a signaling flow diagram of the transition process from distributed transmission to intensive transmission is shown in FIG. 4 and includes the following steps.

The BS monitors a change in the time domain of the uplink transmission channel quality of the UE, and if the change is slow, transmits measurement control signaling to the UE (401) to measure the frequency domain selective fading degree in the downlink channel Instruct the UE to report the report and the measured report status. If the BS indicates the measurement report status, the UE may indicate the measurement report threshold or the period in which the UE reports the measurement report. After the UE receives the measurement control signaling, the UE starts to measure the frequency domain selectivity in the downlink channel of the UE and, if the reporting condition is satisfied, selects the measured fading selectivity value in the frequency domain in the downlink channel. To report, a measurement report 402, or an event reflecting a change in frequency domain selectivity of fading in the downlink channel, is sent to the BS. After receiving the frequency domain selectivity report or event report from the UE, the BS converts the downlink transmission of the UE from distributed transmission to intensive transmission based on the frequency domain selectivity change degree of the fading of the UE or the received event report. Determine whether or not. If it is determined to switch the transmission mode, the BS sends a transition indicator 403 from the distributed transmission to the concentrated transmission to the UE.

After the UE receives the transition indicator 403, it sends a centralized CQI report 404 to the BS and begins to send a CQI report of several CQI report frequency subbands to the BS. After receiving the centralized CQI report, the BS makes a channel assignment for the UE based on the CQI of the various CQI reported frequency subbands, sends the centralized channel assignment signaling 405 to the UE, and which frequency subbands transmit data. Indicates to the UE whether it is used to Thereafter, the BS sends the centralized data transmission 406 to the UE.

5 shows a signaling flow diagram of a transition process from centralized transmission to distributed transmission, and the process includes the following steps.

The BS monitors a change in the time domain of the uplink transport channel quality of the UE, and when the change is fast, i.e., the degree of change in the time domain of the uplink channel of the UE measured by the BS satisfies a predetermined state. If so, the BS sends a transition indicator 503 from the centralized transmission to the distributed transmission to the UE. And, if the change is slow, the BS determines whether the CQI of several CQI reporting frequency subbands transmitted from the UE to the BS can reflect the frequency domain selective fading degree of the downlink channel, that is, the frequency in the intensive CQI reporting. It will continue to determine whether the number of subbands can reflect the frequency domain selective fading degree of the entire frequency band, and if it can be determined, the BS determines the frequency domain selective fading degree based on the intensive CQI report. Then, it is determined whether to transmit the transition indicator 503 from the centralized transmission to the distributed transmission to the UE based on the frequency domain selective fading degree. However, if the centralized CQI transmitted from the UE to the BS is a CQI of the partial CQI reporting frequency subband and cannot be used to determine the frequency domain selective fading degree of the entire frequency band, the BS uses the measurement control signaling 501 for the UE. Transmit to the UE to instruct the UE to report the measurement status and the reporting status of the UE reflecting the frequency domain selective fading degree of the downlink channel. If the BS indicates the measurement report status, it can indicate the measurement report threshold to the UE, or can indicate the period in which the UE reports the measurement report. After the UE receives the measurement control signaling, it begins to measure the frequency domain selectivity in its downlink channel, and if the reporting condition is satisfied, report the measured value of the fading in the downlink channel in the selected frequency To do this, a measurement report 502 or an event reflecting a change in frequency domain selectivity of fading in the downlink channel is sent to the BS. After the BS receives the frequency domain selective report or event report from the UE, whether to convert the UE's downlink transmission from the centralized transmission to the distributed transmission based on the degree of frequency domain selectivity change of the BS's fading or the reported event. Judge. If it is determined to convert, the BS sends a transition indicator 503 from the centralized transmission to the distributed transmission to the UE.

After the UE receives the transition indicator 503, it sends a distributed CQI report 504 to the BS, and sends an average CQI report of the entire frequency band to the BS. After the BS receives the distributed CQI report, the BS allocates a channel for the UE based on the reported CQI value, transmits distributed channel assignment signaling 505 to the UE, and which distributed frequency subbands transmit data. Instructs the UE whether to be used. Thereafter, the BS sends the distributed data transmission 506 to the UE.

Specific operational steps of the BS and the UE in the two transition processes are as follows.

In the transition process from distributed transmission to intensive transmission, the operation flow diagram of the BS is shown in FIG. 6, and the steps are as follows.

In the process by which the BS sends distributed data transmission 602 to the UE, the BS monitors the change in the time domain of the uplink channel quality of the UE (603), and the change in the time domain of the uplink channel of the UE is slow. If it is determined that it is not slow, it proceeds and monitors distributed transmissions, and if it is determined to be slow, the BS transmits measurement control signaling 605, and frequency-domain selective fading of the downlink channel. Instruct the UE to report the measurement report reflecting the degree and the reporting status of the UE. When the BS indicates the measurement report status, the measurement report threshold may be instructed to the UE or may indicate a period of the measurement report of the UE. The BS then begins to receive a measurement report that reflects the frequency domain selective fading of the downlink channel or an event that reflects the degree of change 606 transmitted by the UE, and the transition state from distributed transmission to convergent transmission is If it is not satisfied, it is determined 607, and if not satisfied, proceeds to receiving a measurement report 606, and if the transition state is satisfied, sends a transition indicator from distributed transmission to convergent transmission to the UE ( 608). Thereafter, it starts receiving the centralized CQI report 609 transmitted from the UE, allocates a channel for the UE based on the reported CQI value of various frequency bands, and sends the centralized channel assignment indicator 610 to the UE. . Thereafter, the centralized data transmission may be sent to the assigned channel 611 to complete the transfer mode transition process.

In the transition process from distributed transmission to intensive transmission, the operation flowchart of the UE is shown in the following steps as shown in FIG.

Upon receiving the measurement control signaling 702 instructing the UE to report the frequency domain selectivity measurement report of the downlink channel fading and the reporting status, the UE begins to perform the corresponding measurement 703. Then, it is determined 704 whether the report status is satisfied, if not satisfied, the measurement and judgment continue, and if satisfied, the measurement report of frequency domain selectivity of fading is transmitted 705 or Send an event to the BS reflecting the change in frequency domain selectivity. Thereafter, the UE monitors 706 whether it has received a mode transition indication from the distributed transmission to the central transmission sent from the BS, and if not, continues the measurement and reporting, and receives the mode transition indication if In one case, a CQI report is sent to the BS to report the CQI of the frequency subbands (707). Then, receiving the concentrated channel allocation signaling transmitted from the BS (708), the BS knows which frequency subbands to transmit data to, and is able to receive the concentrated data transmission in the predetermined frequency bands (709). Therefore, the transfer mode transition process is completed.

In the transition process from the centralized transmission to the distributed transmission, the operation flow diagram of the BS is shown in the following steps as shown in FIG.

In the process of the BS transmitting the centralized data transmission 802 to the UE, the BS monitors 803 the change in the time domain of the uplink channel quality of the UE and then in the time domain of the uplink channel of the UE. It is determined 804 whether the change of P is slow, and if the change is not slow, it transmits a transition indicator to the UE (809) and instructs the UE to convert from concentrated transmission to distributed transmission. If the change is slow, the BS continues to determine whether the frequency domain selectivity of the fading can be determined based on the current CQI report of the concentrated transmission (805), and if so, the BS determines the frequency of the channel fading. Based on the region selectivity, it is determined whether the state for converting from the centralized transmission to the distributed transmission is satisfied (808), if not satisfied, the BS transmits measurement control signaling to the UE (806), downlink Instruct the UE to report the frequency domain selectivity measurement report and report status of channel fading. When the BS indicates the measurement report status, the BS may indicate the measurement report threshold to the UE and may also indicate the period in which the UE reports the measurement report. Then, the measurement report of the event reflecting the measurement value of the frequency domain selectivity of the downlink channel fading transmitted from the UE or the frequency domain selectivity change degree of the downlink channel fading is received (807). Thereafter, based on the frequency domain selectivity measurement report or the event report of channel fading, it is determined whether the state for converting from the centralized transmission to the distributed transmission is satisfied (808).

After executing decision 808, if the result of this decision is NO, the BS continues to execute step 805. If the determination result is YES, the BS sends a transition indicator 809 to the UE, instructing the UE to switch from the concentrated transmission mode to the distributed transmission mode. The BS then receives the distributed CQI report sent from the UE (810), sends a channel allocation indicator of distributed transmission to the UE based on the reported CQI, and finally sends the distributed transmission to the channel indicated to the UE. 812, the transition from the centralized transmission mode to the distributed transmission mode is completed.

In the transition process from the centralized transmission to the distributed transmission, the operation flowchart of the UE is shown in the following steps as shown in FIG.

If the UE is in the intensive transmission process, the UE monitors whether measurement control signaling is being transmitted from the BS (902) to determine whether the BS requests to report a measurement report of downlink channel fading frequency domain selectivity. do. If not requested, the UE continues to monitor whether there is a transmission mode transition indicator from the BS (906). If there is a request, the UE measures frequency domain selectivity of downlink channel fading (903). Thereafter, the UE determines whether the reporting state is satisfied (904), if not satisfied, continues with step 903, and if satisfactory, frequency domain selectivity measurement report or frequency of downlink channel fading An event report reflecting the degree of change in the selectivity of fading in the region is sent to the BS (905), and then step 906 is executed to determine whether a transmission mode transition indicator is being transmitted from the BS (906).

After executing decision 906, if the decision result is NO, the UE executes step 902, and if the decision result is YES, sends a distributed CQI report to the BS (907), and then from the BS. The transmitted distributed channel allocation indicator is received, and finally, the distributed transmission transmitted from the BS can be received in the allocated distributed channel (909), thereby completing the transition from the centralized transmission to the distributed transmission.

1 is a signaling flow diagram illustrating a transition process from distributed transmission to converged transmission in IEEE802.16E.

2 is a signaling flow diagram illustrating a transition process from centralized transmission to divisional transmission of IEEE802.16E.

3 is a signaling flow diagram illustrating a transition process between distributed and centralized transmission in accordance with the present invention.

4 is a signaling flow diagram illustrating a transition process from distributed transmission to centralized transmission in accordance with the present invention.

5 is a signaling flow diagram illustrating a transition process from centralized transmission to distributed transmission in accordance with the present invention.

6 is an operational flow diagram of a BS illustrating a transition process from distributed transmission to centralized transmission in accordance with the present invention.

7 is an operational flow diagram of a UE illustrating a transition process from distributed transmission to intensive transmission according to the present invention.

8 is an operational flowchart of a BS illustrating a transition process from centralized transmission to distributed transmission according to the present invention.

9 is an operational flowchart of a UE illustrating a transition process from centralized transmission to distributed transmission according to the present invention.

In order to clearly show the method proposed in the present invention, an example is described below.

An example of a transition from distributed transmission to intensive transmission is described first.

Assume that the current downlink data transmission of the UE is distributed transmission, the UE is a slow moving UE, and the change in the time domain of the channel is slow. During transmission, the BS monitors the change in the time domain of the uplink transmission channel quality of the UE, and it is appropriate for the BS to measure the deviation of the SNR in the uplink transmission subcarrier. If the measured deviation of the SNR is lower than the predetermined threshold for a certain period, the BS may determine that the change in the time domain of the channel of the UE is slow, that is, the UE is moved to a slow speed. In this channel state, concentrated transmission may be a suitable downlink transmission mode for the UE.

However, in terms of the flat fading channel, distributed transmission is an optimal transmission method in the flat fading channel because distributed transmission can obtain the same transmission gain as the centralized transmission, and the corresponding uplink reporting CQI signaling load is relatively low. . Therefore, since detailed determination is required to be performed based on the frequency domain selectivity of the downlink channel fading of the UE, the BS transmits measurement control signaling to the UE to report the frequency domain selectivity measurement report of the downlink channel fading. Ask the UE. On the other hand, when the BS requests the UE to report a measurement report, the BS can also transmit the corresponding measurement report status. For example, the BS transmits a threshold of the measurement report, and if the measurement is larger than the threshold, causes the UE to transmit the measurement report and the event report to the BS to indicate a result of comparing the measured value and the threshold, or determined When a reporting period, for example, the BS transmits a reporting period of 10 ms, the UE sends a measurement report every 10 ms to the BS to report the measured value.

After receiving the measurement control signaling requesting that the UE report the frequency domain selectivity measurement of the downlink channel fading, the UE begins to make this measurement. In this embodiment, the measurement indicating the selectivity of downlink channel fading in the frequency domain is obtained by subtracting the minimum CQI from the maximum CQI difference (CQI_difference_max) of the various CQI reporting frequency subbands, that is, the maximum CQI of all CQI reporting frequency subbands. It's a car. Thus, the UE The SNRs of all CQI frequency subbands can be measured, and based on this, the CQI values of all frequency subbands can be determined, and the CQI_difference_max values to be reported can be calculated. The UE will refer to the measurement report status sent by the BS. In this embodiment, the measurement report state is used to determine whether the measured CQI_difference_max value is greater than the reporting threshold indicated by the BS.

If the reporting status is satisfied, the UE sends an event report to the BS to inform that the CQI_difference_max value has exceeded the reporting threshold indicated by the BS. Since frequency-domain selective fading appears relatively large in the downlink channel, using the centralized transmission achieves a relatively large scheduling gain. As such, the BS will send an indication signaling to the UE to convert from distributed transmission to concentrated transmission based on this event.

After the UE receives the transition indicator signaling, the UE sends a centralized CQI report to the BS to report the CQI values of several frequency subbands. The BS allocates a converged channel for the UE based on the concentrated CQI reported by the UE, and then performs concentrated transmission on these concentrated channels, thereby completing the mode transition process from distributed transmission to concentrated transmission.

The following shows an example of a transition from intensive transmission to distributed transmission.

It is assumed that downlink data transmission of the current UE is intensive transmission and that the total number of CQI reporting frequency subbands of the system is eight.

The BS first monitors the change in the time domain of the uplink transmission channel quality of the UE, for example, the deviation of the SNR in the uplink transmission subcarrier.

If this deviation is greater than a fixed value for a period of time, this indicates that the UE is a fast-moved UE, and since the proper transmission mode is distributed transmission, the BS sends a transition indicator from centralized transmission to distributed transmission signaling directly to the UE. Done.

If this deviation is lower than a predetermined value for a period of time, this indicates that the UE is moved at a slow speed, and the selectivity of downlink channel fading in the frequency domain needs to be sequentially monitored. Here, it is necessary to consider the UE's intensive CQI reporting method, and if the UE's intensive CQI reporting is CQI reporting of the entire frequency band, that is, when the UE reports the CQI value to the BS for each CQI reporting frequency subband, the BS Any other additional measurement report is no longer needed, and based on the intensive CQI report, one can directly determine the selectivity of downlink channel fading in the frequency domain, whereby the transition indicator from centralized transmission to distributed transmission is determined by the UE. It can be determined whether to send to.

However, in current intensive CQI reporting methods, most of them report only the CQIs of some frequency subbands with the best channel quality, and as such, based on these CQI reporting of these frequency subbands, the BS It is often difficult to determine the degree of frequency domain selective fading. In this embodiment, assuming that the UE reports only the three frequency subbands with the best channel quality among the eight frequency subbands, in order to obtain frequency domain selectivity of the downlink channel fading, the BS may select the downlink channel from the UE. Measurement reports that reflect fading will be needed. In this case, the BS transmits measurement control signaling to the UE to indicate a reporting threshold of CQI_difference_max, and informs the event report of the maximum reported CQI difference, that is, CQI_difference_max and the indicated reporting threshold comparison result in the CQI reporting frequency subband. After the UE receives this indication, it measures the CQI values of all frequency subbands, calculates CQI_difference_max, and sends a corresponding event report to the BS if it finds that CQI_difference_max is lower than the reporting threshold. After the BS receives the event report, if it finds that the frequency domain selective fading in the downlink channel is relatively small, then the channel is almost flat fading channel, so the distributed transmission mode is more suitable, so the BS is distributed in the converged transmission. The mode transition indicator to the transmission will be sent to the UE. After the UE receives this mode transition indicator, it sends a distributed CQI report to the BS, which allocates a distributed transport channel for the UE based on the distributed CQI report sent from the UE, and then to the assigned distributed channel. Distributed transmissions are made, thus completing the mode transition process from centralized transmission to distributed transmissions.

BS of the present invention can select a transmission mode more suitable for downlink transmission based on the changing characteristics of the channel in the time domain and frequency domain. When selecting a transmission mode, the variation characteristic of the frequency domain is also taken into account, but the traditional method is to select the transmission mode only according to the variation characteristic of the time domain, and the new method is a channel in which downlink transmission is similar to flat fading. By enabling distributed transmission under conditions, it reduces uplink signaling overhead without reducing transmission gain.

Claims (13)

In the transition method between the distributed transmission mode and the concentrated transmission mode, a) the base station (BS) transmitting a measurement control message to the user terminal (UE); b) the UE performing the measurement and sending a requested measurement report message to the BS; c) the BS sending a new mode transition indicator message to the UE based on a measurement report message sent from the UE; And d) reporting a new mode channel quality indicator (CQI) between the UE and the BS and performing downlink transmission. The method of claim 1, wherein the mode comprises a distributed transmission mode and a concentrated transmission mode. 3. The method of claim 2, wherein the distributed transmission mode reports a single CQI to the BS for the entire frequency band for the UE. 3. The method of claim 2, wherein the centralized transmission mode reports CQIs for sub-frequency bands to the BS for the UE. 2. The method of claim 1 wherein the measurement control message, the measurement report message, and the transition indicator message are radio resource control interface signaling. 2. The method of claim 1, wherein in step d) the CQI reporting of the new mode is signaling of a physical layer interface. 2. The method of claim 1 wherein in step a) the measurement control message comprises a measurement performed by the UE. 2. The method of claim 1, wherein in step a) the measurement control message includes a reporting state to be measured by the UE. 2. The method of claim 1, wherein in step a) the measurement control message comprises a threshold indicated by the BS to the UE. 2. The method of claim 1, wherein in step a) the measurement control message comprises a period of measurement report indicated by the BS to the UE. 2. The method of claim 1 wherein the measurement report message sent from the UE in step b) includes a measurement report reflecting downlink channel fading selectivity in a frequency band. 2. The method of claim 1 wherein the measurement report message sent from the UE in step b) is of event type. 13. The method of claim 12, wherein the event type reflects a comparison result of a measurement measured by the UE and a threshold indicated by the BS.

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